Semiconductor device with ferooelectric hafnium oxide and method for forming semiconductor device

ABSTRACT

The present disclosure provides a semiconductor device comprising a substrate, an undoped HfO 2  layer formed over the substrate and a TiN layer formed on the HfO 2  layer. Herein, the undoped HfO 2  layer is at least partially ferroelectric. In illustrative methods for forming a semiconductor device, an undoped amorphous HfO 2  layer is formed over a semiconductor substrate and a TiN layer is formed on the undoped amorphous HfO 2  layer. A thermal annealing process is performed for at least partially inducing a ferroelectric phase in the undoped amorphous HfO 2  layer.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to semiconductor devices, and, more particularly, to complex semiconductor devices with ferroelectric hafnium oxide, and a method for forming an according semiconductor device.

2. Description of the Related Art

Integrated circuits typically comprise a very large number of circuit elements formed on a given area of a chip, wherein a semiconductor device represents an important implementation of a circuit element. For example, current advanced ICs (integrated circuits) are formed by millions of field effect transistors, which are also referred to as MOS transistors or MOSFETS, and in general MOSFETs may be considered as dominant semiconductor devices in modern ICs. Efforts towards increased performance and low integration volume have, therefore, been mainly directed to reducing the size of basic transistor structures. A drive to continuously improve the performance of semiconductor devices is given by Moore's law of scaling, which demands that the number of semiconductor devices in an IC increases exponentially, e.g., doubling over a two or three year period. As a consequence, minimum feature sizes of transistors have decreased exponentially with about each year.

Despite a plurality of scaling reducing process technologies having been developed and practiced so as to comply with Moore's law, it is clear that scaling cannot go on forever, particularly as constraints imposed by materials become increasingly important at advanced scaling nodes. For example, the thickness of a gate dielectric layer in a gate electrode of an advanced transistor structure has become so thin (under 2 nm) that a gate leakage current caused by direct tunneling of electrons from the gate electrode into a channel region (generally located underneath the gate electrode) increases with decreasing layer thickness and, as a result, the power dissipation of any integrated circuit based on such transistors becomes unacceptable.

In using high-k dielectric materials, the gate leakage problem can be addressed by providing gate dielectrics with high-k dielectric materials, such as hafnium oxide-based materials, which allows increasing the capacitive coupling of the gate electrode to the channel without reducing the thickness of the gate dielectric. Therefore, the implementation of gate dielectrics by means of high-k dielectric materials allows not only increasing the performance of individual transistor elements, but also reducing the dimensions of semiconductor devices and consequently incorporating increased functionality into a given chip area.

Further efforts to increase the functionality built into a given chip area resulted in approaches to eliminate secondary storage systems. These approaches are based on the development of non-volatile memory devices which do not lose stored information when power supply is lost. Herein, efforts are directed to the development of ferroelectric RAMs or FeRAM devices which make use of dielectric layers with ferroelectric properties. Current FeRAMs appear to show, in comparison with conventional flash memory devices, lower power usage at higher writing performances and a greater number of write-erase cycles. Consequently, intensive investigations have been conducted to ferroelectric materials in order to provide non-volatile memory devices.

Therefore, ferroelectric materials have been considered for forming highly efficient capacitors. The effect that one makes use of herein is the possibility to adjust the polarization state of a ferroelectric material on the basis of appropriate electrical fields which are applied to the ferroelectric material. Since the polarization state of a ferroelectric material is preserved unless it is exposed to a high, with regard to the polarization state counter-oriented electrical field, or a high temperature, it is possible to “program” a capacitor formed of ferroelectric material such that an induced polarization state reflects an information unit. The reason is that an induced polarization state may be preserved, even upon removing a “programmed” capacitor from a power supply. Opposed to conventional storage capacitors of known flash memory designs, a refreshment of the state of the capacitor is not required. Another advantage of ferroelectric materials is the comparatively high dielectric constant of ferroelectric materials (k greater than 4) which may enable fabricating semiconductor devices with superior performance as compared to conventional semiconductor devices.

Although a ferroelectric field effect transistor or a ferroelectric capacitor represent in theory very promising concepts for complex semiconductor devices, it is a difficult task to identify appropriate ferroelectric materials which are compatible with existing manufacturing processes, particularly at advanced technology nodes. For example, commonly known ferroelectric materials, such as PZT or perovskites, are not compatible with standard CMOS processes. However, recent research results indicate that hafnium oxide-based dielectric materials may represent promising candidates for materials with ferroelectric behavior. To date, it is known that hafnium (Hf) rich materials exhibit a predominantly monoclinic structure with paraelectric behavior and pure HfO₂ is known to be of paraelectric nature. With regard to hafnium-based materials, however, recent results indicated that the monoclinic structure is suppressed in Zr, Si, Y and Al-doped hafnium oxide materials and stabilized crystal structures of ferroelectric nature were obtained in accordingly-doped samples. Examples of ferroelectric hafnium-based materials are, for example, discussed in Mueller et al., “Incipient Ferroelectricity in Al-doped HfO₂ Thin Films,” Adv. Funct. Mater., 22:2412-17 (2012), Mueller et al., “Ferroelectricity in yttrium-doped hafnium oxide,” J. Appl. Phys., 110:114113 (2011), Mueller et al., “Ferroelectricity in Simple Binary ZrO₂ and HfO₂ ,” Nanoletters, 12:4318-23 (2012), and Boeske et al., “Phase Transitions in Ferroelectric Silicon-doped Hafnium Oxide,” Appl. Phys. Lett., 99:112904 (2011).

Presently, the ferroelectric nature of some hafnium-based materials as opposed to the paraelectric nature of hafnium rich materials is considered as originating from an appropriate crystalline state being established in accordingly-doped hafnium oxide material which provides the ferroelectric nature was not observed that pure hafnium oxide does not have due to its monocline crystal structure.

Although ferroelectric material on the basis of hafnium oxide may be expected to show a better compatibility with existing CMOS processes, several drawbacks for ferroelectric non-volatile memory devices are observed in actual implementations. Particularly, the doping of a deposited ferroelectric hafnium oxide layer, for instance in the framework of an ALD process, raises a lot of issues with regard to how to include the doping of the ferroelectric hafnium oxide layer into the ALD sequence. For instance, a necessarily complex recipe structure for including dopants into ferroelectric hafnium oxide reduces the throughput of existing process flows. Particularly in ALD processes, additional doping precursors are necessary that usually suffer from low-ALD capability. It is observed that doping in ALD processes is not possible to a sufficient degree. For hafnium oxide, there is a narrow process window for establishing a ferroelectric phase by including dopants into the hafnium oxide, leading to difficult process control, for example with XPS-analysis, and bad doping uniformity. As large fluctuations of device parameters occur across wafers, it is not possible, for example, to provide sufficient memory window uniformity for ferroelectric FET devices.

In view of the above-described state in the art, it is desirable to provide a semiconductor device with incorporated ferroelectric behavior in good compatibility with standard manufacturing techniques and without deteriorated performance of fabricated semiconductor devices and lowering throughput. It is further desirable to provide a method for forming a semiconductor device with ferroelectric properties in agreement with standard CMOS processes and particularly which can be included into standard processes without inferring complex recipe structures.

SUMMARY OF THE INVENTION

The following presents a simplified summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not an exhaustive overview of the invention. It is not intended to identify key or critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is discussed later.

The present disclosure provides a semiconductor device and a method for forming a semiconductor device, wherein a semiconductor substrate having an undoped ferroelectric hafnium oxide material layer is provided.

In one aspect of the present disclosure, a semiconductor device is provided. In some illustrative embodiments herein, the semiconductor device includes a substrate, an undoped HfO₂ layer formed over the substrate and a TiN layer formed on the HfO₂ layer, wherein the undoped HfO₂ layer is at least partially ferroelectric.

In another aspect of the present disclosure, a method for forming a semiconductor device is provided. In some illustrative embodiments herein, the method includes forming an undoped amorphous HfO₂ layer over a substrate, forming a TiN layer on the undoped amorphous HfO₂ layer and performing a thermal annealing process for at least partially inducing a ferroelectric phase in the undoped amorphous HfO₂ layer.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosure may be understood by reference to the following description taken in conjunction with the accompanying drawings, in which like reference numerals identify like elements, and in which:

FIGS. 1 a-1 c schematically illustrate methods for forming a semiconductor device in accordance with some illustrative embodiments of the present disclosure;

FIG. 2 schematically illustrates a graphical relation representing ferroelectric behavior of a hafnium oxide material layer in accordance with an illustrative embodiment of the present disclosure;

FIG. 3 a schematically illustrates a FeFET device structure in accordance with an illustrative embodiment of the present disclosure; and

FIG. 3 b schematically illustrates a capacitor structure in accordance with an illustrative embodiment of the present disclosure.

While the subject matter disclosed herein is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

DETAILED DESCRIPTION

Various illustrative embodiments of the invention are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.

The present disclosure will now be described with reference to the attached figures. Various structures, systems and devices are schematically depicted in the drawings for purposes of explanation only and so as to not obscure the present disclosure with details which are well known to those skilled in the art. Nevertheless, the attached drawings are included to describe and explain illustrative examples of the present disclosure. The words and phrases used herein should be understood and interpreted to have a meaning consistent with the understanding of those words and phrases by those skilled in the relevant art. No special definition of a term or phrase, i.e., a definition that is different from the ordinary or customary meaning as understood by those skilled in the art, is intended to be implied by consistent usage of the term or phrase herein. To the extent that a term or phrase is intended to have a special meaning, i.e., a meaning other than that understood by skilled artisans, such a special definition shall be expressively set forth in the specification in a definitional manner that directly and unequivocally provides the special definition for the term or phrase.

The present invention relates to semiconductor devices integrated on a chip and to semiconductor device structures integrated on a chip. Semiconductor devices may, for example, be given by metal oxide semiconductor devices (MOS devices), capacitors, e.g., MIM/MIS capacitors, resistor structures or the like. When referring to MOS devices, the person skilled in the art will appreciate that although the expression “MOS device” is used, no limitation to a metal-containing gate material and/or to an oxide-containing gate dielectric material is intended. When referring to MIM/MIS capacitors, the person skilled in the art will appreciate that although the expression “MIM/MIS” is used, no limitation to a metal-containing electrode is intended. Semiconductor devices of the present disclosure, and particularly MOS devices and/or capacitors as illustrated by means of some illustrative embodiments as described herein, concern elements fabricated by using advanced technologies. Semiconductor devices of the present disclosure are fabricated by technologies applied to approach technology nodes smaller than 100 nm, preferably smaller than 50 nm, more preferably smaller than 35 nm. The person skilled in the art will appreciate that the present disclosure suggests semiconductor devices having structures with minimal length and/or width dimensions smaller than 100 nm, preferably smaller than 50 nm, more preferably smaller than 35 nm.

The person skilled in the art understands that MOS transistors may be fabricated as P-channel MOS transistors or PMOS transistors and as N-channel transistors or NMOS transistors, and both may be fabricated with or without mobility enhancing stressor features or strain-inducing features. A circuit designer can mix and match device types, using PMOS and NMOS transistors, stressed and unstressed, to take advantage of the best characteristics of each device type as they best suit the circuit being designed. The person skilled in the art understands that stress and strain may be generally described with regard to the tensile modulus.

In describing the following figures, semiconductor devices and methods of forming semiconductor devices in accordance with various exemplary embodiments of the present disclosure will be illustrated. The described process steps, procedures and materials are to be considered only as exemplary embodiments designed to illustrate to one of ordinary skill in the art, methods for practicing the invention. However, it is to be understood that the invention is not exclusively limited to the illustrated and described exemplary embodiments, as many possible modifications and changes exist which will become clear to the ordinary person skilled in the art when studying the present detailed description together with the accompanying drawings and the above background and summary of the invention. Illustrated portions of semiconductor devices may include only a single element, although those skilled in the art will recognize that actual implementations of semiconductor devices may include a large number of such elements. Various steps in the manufacture of semiconductor devices are well known and so, in the interest of brevity, many conventional steps will only be mentioned briefly herein, or will be omitted entirely without providing the well-known process details.

Recent measurements indicated that thin films of doped hafnium oxide can produce a spontaneous polarization at intermediate doping levels, potentially resulting in usable ferroelectric hysteresis loops in these layers. For example, Y:HfO₂ thin films with a YO_(1.5) content of 5.2 mol % show a ferroelectric hysteresis with remanent polarization Pr of 24 μC/cm². A thin Si:HfO₂ film was shown to exhibit a ferroelectric hysteresis with remanent polarization Pr of 10 μC/cm² at an SiO₂ content of 3.4 mol %. Furthermore, in ZrO₂ doped hafnium oxide material, a remanent polarization Pr of 15 μC/cm² was observed at an admixture of 50 mol % ZrO₂.

Data obtained in the above presented examples suggests that the structural origin of spontaneous polarization in doped HfO₂ is linked to the stabilization of the orthorhombic phase in doped hafnium oxide. Although hafnium oxide-based thin films show a ferroelectric behavior and, by incorporating an appropriate dopant structure into hafnium oxide, it seems possible to achieve high density ferroelectric memories, an implementation in existing processes for integrating ferroelectrics in microelectronic devices shows severe drawbacks as described above with regard to the state in the art.

In view of the present situation, it is proposed to form an undoped amorphous HfO₂ layer over a substrate, for example, by means of an ALD process. Thereafter, a TiN layer is formed on the undoped amorphous HfO₂ layer. The inventors could show that an undoped HfO₂ layer of ferroelectric nature can be manufactured.

The person skilled in the art will appreciate that ferroelectric material layers of undoped hafnium oxide can be easily implemented in existing process flows such that, given the vast experience in integrating HfO₂ based thin films into advanced semiconductor devices, ferroelectricity can be easily provided by existing processes without affecting the reliability and scaling properties to be achieved for complex semiconductor devices. Particularly, the scaling of ferroelectric non-volatile memory devices can be positively affected.

With regard to FIGS. 1 a-1 c, some illustrative embodiments of the present disclosure will be described in greater detail. FIG. 1 a schematically shows a semiconductor device 100 in accordance with an illustrative embodiment of the present disclosure at an early stage during fabrication. At this stage, a semiconductor substrate 102 is provided. The substrate 102 may comprise a semiconductor material which may be selected from silicon, germanium, silicon/germanium, silicon/germanium/carbon, silicon/carbon, gallium arsenide, indium arsenide, indium phosphate and other appropriate semiconductor materials. In some illustrative embodiments, the substrate 102 may comprise silicon. The person skilled in the art will appreciate that the substrate 102 may be a single crystalline silicon layer having a surface orientation, i.e., a crystallographic orientation of the surface normal of a top surface of the substrate 102 being one of a major crystallographic orientation. In some illustrative embodiments, the substrate 102 may be one of a bulk substrate, a semiconductor-on-insulator (SOI) substrate and a hybrid substrate. The substrate 102 may have a strain or stress built in for enhancing the mobility of majority charge carriers. Additionally, or alternatively, the substrate 102 may be doped, such as having one or more well regions. This does not pose any limitation to the present disclosure and, at the stage as shown in FIG. 1 a, the substrate 102 may be undoped.

In some illustrative examples, an optional layer 106 may be formed on the semiconductor substrate 102. For example, the optional layer 106 may comprise one of TiN, SiO₂ and SiON. Alternatively, the optional material layer 106 may be omitted, as it is indicated by a broken line in FIG. 1 a.

An amorphous undoped HfO₂ layer 122 is formed over the substrate 102. In some illustrative examples herein, the amorphous undoped HfO₂ layer 122 may be disposed on the substrate 102, i.e., the amorpous undoped HfO₂ layer may be in direct contact with the underlying substrate 102. In alternative embodiments, the amorphous undoped HfO₂ layer 122 may be disposed on the optional material layer 106.

In accordance with illustrative embodiments of the present disclosure, the amorphous undoped HfO₂ layer 122 may be formed by performing an ALD process 120 for depositing the amorphous undoped HfO₂ layer 122. In some special examples herein, a deposition temperature may be in a range from about 200-400° C., such as, for example, from about 200-300° C. In some advantageous implementations of the present disclosure, the deposition temperature is less than 300° C., or even less than 250° C.

A thickness of the deposited undoped amorphous HfO₂ layer 122 may be in a range between about 4-20 nm. In some advantageous implementations of the present disclosure, the HfO₂ layer 122 is formed with decreasing thickness, such as less than 10 nm, or even less than 6 nm. In an explicit example of the present disclosure, the undoped HfO₂ layer 122 may be 6 nm thick, without posing any limitation to the present disclosure.

FIG. 1 b depicts the semiconductor device 100 at a more advanced stage during fabrication in which a capping layer is formed on the undoped amorphous HfO₂ layer 122. In illustrative embodiments of the present disclosure, the capping layer may comprise a TiN layer 132 or even be given by the TiN layer 132. In an illustrative example, the undoped amorphous HfO₂ layer 122 may be fully covered by the TiN layer 132.

In some illustrative examples herein, the TiN layer 132 has an average oxygen content in a range from about 2-30%, for example, in a range from about 2-20%, and, for best results, in a range from about 2-15%. The average oxygen content may be, for example, determined by determining the oxygen content in a given volume of TiN material of the TiN layer 132, and the average oxygen content may be obtained by extrapolating the oxygen content of the given volume. Accordingly, an extrapolated value may be obtained which represents the averaged oxygen content across the TiN layer 132. The averaging may be improved by extrapolating the oxygen content of a plurality of preset measurement volumes and averaging the extrapolated values. The person skilled in the art will appreciate that this does not pose any limitation to the present disclosure and merely serves to illustrate a possibility to obtain an average value. In some advantageous implementations of the present disclosure, the HfO₂ layer 122 is formed with decreasing oxygen content, such as less than 10%, or even less than 5%.

In some illustrative examples, the TiN layer may have a bulk resistivity of greater than about 100 μΩcm and smaller than about 400 μΩcm, such as, for example, smaller than about 350 μΩcm, and, for best results, smaller than about 300 μΩcm.

In some illustrative examples, the TiN layer 132 may have a density in a range from about 4.5-5.2 g/cm³, and, for best results, in a range from about 4.55-5.15 g/cm³.

In some special illustrative examples, the TiN layer 132 may have a compressive internal stress in a range from about 200-1500 MPa. For example, the compressive internal stress of the TiN layer 132 may be at about 250 MPa or greater.

In some special illustrative embodiments of the present disclosure, an oxygen content distribution along a depth direction of the TiN layer 132, i.e., parallel to a normal direction of an upper surface 132 u of the TiN layer 132, may be formed. For example, the oxygen content profile may be such that an oxygen content at an upper surface 132 u of the TiN layer is in a range from about 5-15% and an oxygen content at an interface of the TiN layer 132 with the undoped amorphous HfO₂ layer 122 is smaller than 7%. In some illustrative examples herein, an oxygen content profile may be provided such that the oxygen content present at an upper surface 132 u of the TiN layer 132 is greater than about 5% and decreases to about 0% at an interface of the TiN layer 132 with the undoped amorphous HfO₂ layer 122. The person skilled in the art will appreciate that, accordingly, an oxygen gradient may be provided in the TiN layer 132, the oxygen gradient being oriented in parallel to a normal direction of the upper surface 132 u. In an explicit example, the oxygen content at the upper surface 132 u may be in a range from 2-5% and the oxygen content at the interface may be below 5%.

In illustrative embodiments of the present disclosure, the TiN layer 132 may be formed in a deposition process 130. In some illustrative embodiments of the present disclosure, the deposition process 130 may comprise a physical vapor deposition (PVD) process. A deposition temperature of the deposition process 130 may be substantially smaller than or equal to about 400° C. and, for best results, smaller than or equal to about 300° C. In some special illustrative examples herein, the deposition temperature may be substantially about room temperature. For example, the TiN layer 132 may be deposited on the undoped amorphous HfO₂ layer 122 such that the undoped amorphous HfO₂ layer 122 remains amorphous throughout the deposition process 130.

In accordance with some illustrative examples herein, the PVD process may be performed with a specific ratio of titanium/nitrogen which is adjusted during the deposition process 130. For example, the PVD process may be a sputter process.

In a specific illustrative example, a nitrogen/oxygen atmosphere may be established in a process chamber so as to form an oxygen content at an upper surface 132 u of the TiN layer in a range from about 2-15% or 5-10%, and an oxygen content at an interface of the TiN layer 132 with the undoped amorphous HfO₂ layer 122 is smaller than 7%. For example, the nitrogen content may be changed during the deposition process 130 such that a desired oxygen content profile and a desired oxygen gradient may be established across the TiN layer 132. In an explicit example, the oxygen content at the upper surface 132 u may be in a range from about 2-5% and the oxygen content at the interface may be below 5%.

In another specific illustrative example, the deposition process 130 comprises a PVD process which is performed in a nitrogen atmosphere. The person skilled in the art will appreciate that a specific ratio of titanium/nitrogen may be adjusted during the deposition process 130. After the TiN layer 132 is formed, a thermal annealing process may be performed in an oxygen-comprising atmosphere for forming a desired oxygen content profile within the TiN layer 132. For example, an oxygen content profile as indicated above may be formed. In a special illustrative way, an oxygen gradient may be provided within the TiN layer 132. The oxygen gradient may be configured as described above.

FIG. 1 c depicts the semiconductor device 100 at a more advanced stage during fabrication in accordance with some illustrative embodiments of the present disclosure. A thermal annealing process 140 is performed for at least partially inducing a ferroelectric phase in the undoped amorphous HfO₂ layer 122. In some illustrative examples, the TiN layer 132 may fully encapsulate the undoped amorphous HfO₂ layer 122 so as to obtain a fully kept nucleation of HfO₂ layer crystallites during the thermal annealing process 140.

In some illustrative embodiments of the present disclosure, the thermal annealing process may be a rapid thermal anneal process exposing the semiconductor device 100 during the thermal annealing process 140 to temperatures of about 400-1100° C. and, for best results, to about 800° C. The person skilled in the art will appreciate that the annealing temperature may depend on a thickness of the undoped amorphous HfO₂ layer 122 and may be accordingly chosen.

FIG. 2 depicts a hysteresis curve H of a ferroelectric undoped hafnium oxide material, such as the undoped HfO₂ layer 122, after the thermal annealing process 140 is performed.

The diagram depicted in FIG. 2 has an ordinate representing the polarization P (measured in μC/cm²) plotted versus an abscissa representing an applied voltage U (arbitrary units, e.g., in the range of 1-5 V without limiting the present disclosure in this respect). An origin O of the diagram of FIG. 2 denotes zero polarization and zero voltage U, as indicated by broken lines in FIG. 2.

As visible from FIG. 2, ferroelectricity is characterized by the polarization of a material running through a hysteresis between two saturation polarizations P_(sat) and −P_(sat). For example, when increasing the voltage U from U₁ at which the polarization has a minimum polarization −P_(sat) to a maximum voltage U₂, the polarization of the material changes along the curve portion H1 of the hysteresis curve H and becomes saturated (P assumes the saturation polarization P_(sat)). When reducing again the applied voltage U from U₂ at maximum polarization P_(sat) to U₁, the polarization changes as indicated by the curve portion H2 of the hysteresis curve H until the polarization becomes saturated (negative saturation polarization −P_(sat)) at U₁. It is noted that further increasing/decreasing the voltage U beyond the voltage U₂/U₁ does indeed not change the polarization because all dipoles of the ferroelectric materials are aligned in an electric field imposed by the applied voltage and therefore saturation is to be expected.

In, starting from U₂/U₁, reducing/increasing the applied voltage U to zero, the polarization decreases/increases (along H2/H1) to a non-vanishing polarization value P_(r)/−P_(r) at U=0, usually referred to as “remanent polarization.” In dependence on a previously-induced saturation polarization caused by some previously applied voltage, a specific remanent polarization of a ferroelectric material is therefore maintained, even after disconnecting the ferroelectric material from an electrical power source. In this way, a ferroelectric material may be “programmed” into a remanent polarization state, which allows identifying a previously-applied voltage level, i.e., greater or smaller than zero.

The inventors observed a remanent polarization of about 2 μC/cm² in a ferroelectric undoped HfO₂ layer capped by a TiN layer as described above in accordance with some illustrative embodiments that were discussed above with regard to FIGS. 1 a-1 cd and 2. In other experiments involving an undoped HfO₂ layer having a thickness of 6 nm, a remanent polarization of about 10 μC/cm² were observed.

Some illustrative applications of the present disclosure will be further discussed with regard to FIGS. 3 a and 3 b. In FIG. 3 a, a semiconductor device 300 a is depicted. The semiconductor device 300 a may be formed in and on a substrate 302 a. The substrate 302 a may be similar to the substrate 102 as described with regard to FIG. 1 a above. As depicted in FIG. 3 a, the semiconductor device 300 a comprises a gate electrode structure 310 a formed over a surface portion of the substrate 302 a. In an explicit example, the gate electrode structure 310 a may be formed directly on the substrate 302 a. The gate electrode structure 310 a may comprise an optional SiON layer 312 a, an undoped ferroelectric HfO₂ layer 314 a, a TiN layer 316 a and a gate material layer 318, such as a polysilicon material layer. At opposing ends of the gate electrode structure 310 a, a source region 322 and a drain region 324 are formed in the substrate 302 a. The SiON layer 312 a is optional, as indicated by the broken line. This does not pose any limitation to the present disclosure and the person skilled in the art will appreciate that an SiO₂ layer may be formed in place of the SiON layer 312 a, or, alternatively, the ferroelectric undoped HfO₂ layer 314 a may be disposed directly on the substrate 302 a.

In some illustrative embodiments of the present disclosure, the semiconductor device 300 a may be operated as a FeFET. Herein, the source region 322 and the drain region 324 may be coupled to source/drain contacts (not illustrated) and the gate electrode 318 may be coupled to a gate contact (not illustrated). It is understood that the source region 322 may be coupled to a source potential Vs, the drain region 324 may be coupled to a drain potential Vd and the gate structure 310 a may be coupled to a gate potential Vg. The person skilled in the art will appreciate that a quiescent state may be given by Vg=0V, Vd=0V, Vs=0V.

In the following discussion of illustrative operation modes for the semiconductor device 300 a, an N-channel FeFET configuration of the semiconductor device 300 a is assumed. Herein, for example, the substrate 302 a may be at least locally adjacent to the semiconductor device 300 a provided as a P-type well and the source region 322 and the drain region 324 are provided by N-type doped regions embedded into the substrate 302 a. The person skilled in the art will appreciate that, in some illustrative examples, the drain potential Vd may be supplied by first bitlines (not illustrated), the source potential Vs may be supplied by second bitlines (not illustrated) and the gate potential Vg may be supplied by wordlines (not illustrated).

In an N-channel FeFET, programming of the semiconductor device 300 a by turning the ferroelectric undoped HfO₂ layer 314 a into a first polarization state may be achieved by providing a voltage pulse to the gate electrode structure 310 a, wherein the voltage pulse has an amplitude Vp. In some illustrative examples herein, the first polarization state may be associated with the information state “0”. Accordingly, when setting the amplitude of the voltage pulse to −Vp, a second polarization state can be defined in the undoped ferroelectric HfO₂ layer 314 a. The second polarization state may be, for example, identified with the information state “1”. This does not pose any limitation to the present disclosure and, alternatively, the assignment of an information state to a polarization state may be reversed.

With regard to the discussion of FIG. 2 above, the amplitude Vp may be substantially equal to U₂ as discussed with regard to FIG. 2 above. On the other hand, the amplitude −Vp is substantially equal to U₁ as discussed with FIG. 2 above. However, this does not pose any limitation to the present disclosure, and the person skilled in the art will appreciate that an amplitude Vp or −Vp that does not completely induce a saturated polarization state of the undoped ferroelectric HfO₂ layer 314 a may be chosen instead. It is to be understood that, during programming, the potentials Vd and Vs are set to 0V for obtaining best results.

After switching off the programming potential supplied to the gate electrode structure 310 a, a remanent polarization (see P_(r) or −P_(r) in FIG. 2) will remain in the undoped ferroelectric HfO₂ layer 314 a. Therefore, the remanent polarization corresponding to the first polarization state induced by Vp can be associated with the information state “0” and the remanent polarization corresponding to −Vp can be associated with the information state “1” of the semiconductor device 300 a.

A non-vanishing remanent polarization of the undoped ferroelectric HfO₂ layer 314 a results in a shift in the threshold voltage of the semiconductor device 300 a. As the different remanent polarization states of the ferroelectric undoped HfO₂ layer 314 a are associated with different information states “0”, “1”, these different remanent polarization states result after programming in different threshold voltages of the semiconductor device 300 a. Upon determining a current flow between the source region 322 and the drain region 324 when applying a predetermined gate potential to the gate electrode structure 310 a, the different threshold voltages and, accordingly, the different information states “0”, “1” can be determined.

In a special illustrative example herein, reading out from the semiconductor device 300 a may be performed by applying a gate potential Vg=Vr to the gate electrode structure 310 a and a drain potential Vd=Vdr to the drain 322. In explicit examples herein, the source 324 may be coupled to a source potential Vs=0V. It is to be understood that when reading out of information from the semiconductor device 300 a is performed, the information state “0” resulting from a programming by a programming potential “+Vp” results in a greater source/drain current than the information state “1” resulting from the programming with the programming potential “−Vp”. Therefore, the information state “0”, “1” may be distinguished by the amount of current flowing between the source region 322 and the drain region 324 at a preset reading potential Vr applied to the gate electrode structure 310 a and a reading potential Vdr applied to the drain 322. Moreover, the read-out procedure as described above can be non-destructive, i.e., the information state imposed on the gate electrode structure 310 a by a specific polarization state induced in the ferroelectric undoped HfO₂ layer 314 a may be preserved, particularly when selecting a reading potential with an absolute value smaller than the absolute value of the applied programming potential.

The person skilled in the art will appreciate that a method for forming a semiconductor device as provided by the present disclosure is very easily included into existing fabrication process flows of complex semiconductor devices. It is possible to manufacture a high number of semiconductor devices in parallel, wherein ferroelectric characteristics in HfO₂ layers of semiconductor devices may be selectively adjusted or “activated” without the need for dopants and, therefore, without the need to introduce additional doping sequences into existing process flows.

In some illustrative embodiments of the present disclosure, this may be achieved by selectively forming a TiN layer, such as the TiN layer 132 as discussed with regard to FIGS. 1 a-1 c or the TiN layer 316 a as described above with regard to FIG. 3 a, only on selected semiconductor devices by, for example, masking portions over the substrate 302 a in which semiconductor devices are to be fabricated which should not have any ferroelectric characteristic.

In some explicit examples herein, a first and a second semiconductor device may be provided in a first and a second active region of a substrate, such as, for example, a substrate as described above with regard to FIGS. 1 a and 3 a. The first and second active regions may be separated by an insulating structure, such as an STI structure and/or one or more further active regions formed in between.

An undoped amorphous HfO₂ layer may be formed over the first and second active regions such that a first undoped amorphous HfO₂ layer can be formed over the first active region and a second undoped amorphous HfO₂ layer can be formed over the second active region. Accordingly, the first semiconductor device may comprise, at this stage of fabrication, a first undoped amorphous HfO₂ layer and the second semiconductor device may comprise, at this stage of fabrication, a second undoped amorphous HfO₂ layer. The person skilled in the art will appreciate that other active regions which may be possibly present in the substrate may be covered by an appropriate masking structure such that the first and second active regions are exposed to a deposition process for forming the first and second undoped amorphous HfO₂ layers. In some illustrative examples herein, the deposition process may be an ALD process.

Next, a masking structure may be formed over the substrate, the masking structure overlying the first active region and leaving the second active region exposed to further processing. In some illustrative examples herein, a mask or hardmask structure may be formed on the first active region.

Subsequently, a TiN layer may be formed on the second undoped amorphous HfO₂ layer in accordance with formation processes as described with regard to the TiN layer 132 or the TiN layer 316 a above.

After having formed the TiN layer over the second undoped amorphous HfO₂ layer over the second active region, the masking structure of the first active region may be removed and a second masking structure covering the second active region may be formed such that the first active region is exposed to further processing.

A second TiN layer may be formed over the first undoped HfO₂ layer in accordance with conventional techniques, such as known CVD processes. The person skilled in the art will appreciate that upon exposing the second active region to temperatures of 400° C. and more, the ferroelectric properties of the second HfO₂ layer may be activated, while the first HfO₂ layer will not be ferroelectric and show paraelectric properties as known in the art.

Therefore, ferroelectric semiconductor devices and non-ferroelectric semiconductor devices may be easily fabricated in a manner consistent with existing fabrication process flows, i.e., without the need of introducing additional doping processes.

With regard to FIG. 3 b, a further semiconductor device structure 300 b will be described. The semiconductor device structure 300 b comprises a substrate 302 b similar to the substrate 102 as described above with regard to FIGS. 1 a-1 c or the substrate 302 a as described above with regard to FIG. 3 a. Furthermore, a bottom electrode layer 312 b is formed over the semiconductor substrate 302 b. Although FIG. 3 b depicts the bottom electrode 312 b as being directly formed on an upper surface of the substrate 302 b, this does not pose any limitation to the present disclosure, and the person skilled in the art will appreciate that one or more additional layers may be formed in between the bottom electrode 312 b and the substrate 302 b. For example, an insulating layer (not illustrated) may be formed in between the bottom electrode 312 b and the substrate 302 b. Alternatively, an electrically-conducting structure may be formed in between the bottom electrode 312 b and the substrate 302 b. In this case, the person skilled in the art will appreciate that the substrate 302 b may have a doped well region formed therein, at least locally in a region adjacent to the semiconductor device structure 300 b. For example, the bottom electrode 312 b may be coupled by a conducting structure (not illustrated) to a doped region (not illustrated) formed in the substrate 302 b.

An undoped ferroelectric HfO₂ layer 314 b is formed on the bottom electrode 312 b. The undoped ferroelectric HfO₂ layer 314 b may be formed in accordance with a process as described above with regard to FIGS. 1 a-1 c or with regard to FIG. 3 a.

Furthermore, the semiconductor device structure 300 b comprises a TiN layer 316 b formed on the undoped ferroelectric HfO₂ layer 314 b. The TiN layer 316 b is similar to the TiN layer 132 as discussed with regard to FIGS. 1 a-1 c above or to the TiN layer 316 a as discussed with regard to FIG. 3 a above.

In a special illustrative embodiment of the present disclosure, the semiconductor device structure 300 b may form a MIM or MIS capacitor structure. An according semiconductor device structure 300 b may be coupled to a FET device (not illustrated) such that the bottom electrode 312 b may be coupled to one of the source and drain of the FET device (not illustrated). An according combination of a FET device (not illustrated) and the semiconductor device structure 300 b may implement a 1T-1C FeRAM memory cell structure including a conventional, i.e., non-ferroelectric, FET acting as an access transistor, while the semiconductor device structure includes an undoped ferroelectric HfO₂ layer 314 b. The person skilled in the art will appreciate that opposed to a D-RAM memory cell, only one capacitor and one access transistor is used to form the memory cell. Furthermore, the person skilled in the art will appreciate that an according FeRAM structure may be easily formed in accordance with existing fabrication flows without introducing unnecessary doping processes. Therefore, non-volatile memory devices based on ferroelectric FeRAM devices may be provided with a high degree of uniformity across a semiconductor wafer by using existing fabrication process flows without the need of including complex doping processes. A capacitor may be read out in accordance with the discussion of reading and writing operations as described above.

The present disclosure proposes to use a specifically-engineered TiN layer for enabling ferroelectricity in pure HfO₂ material. Therefore, it is possible to have undoped HfO₂ formed with ALD processes and to induce a stable ferroelectric crystalline phase in pure HfO₂. For example, the inventors observed a stabilization effect occurring in ALD deposited pure HfO₂ due to PVD-TiN encapsulation, wherein the TiN layer shows a specific oxygen content profile, such as an oxygen gradient. The ferroelectric pure HfO₂ material provided by the present disclosure shows a higher conformality as compared to HfO₂ deposited by physical vapor deposition processes or doped HfO₂ material formed by ALD processes. Particularly, performing doping in ALD processes makes existing fabrication of semiconductor devices very complex because it is necessary to control a uniform dopant concentration across the wafer.

The particular embodiments disclosed above are illustrative only, as the invention may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. For example, the process steps set forth above may be performed in a different order. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the invention. Accordingly, the protection sought herein is as set forth in the claims below. 

What is claimed:
 1. A semiconductor device, comprising: a substrate; an undoped HfO₂ layer formed over said substrate; and a TiN layer formed on said HfO₂ layer; wherein said undoped HfO₂ layer is at least partially ferroelectric.
 2. The semiconductor device of claim 1, wherein said undoped HfO₂ layer has a thickness in a range from about 1-30 nm or in a range from about 2-20 nm.
 3. The semiconductor device of claim 1, wherein said TiN layer has an average oxygen content in a range from about 2-30% or in a range from about 2-20% or in a range from about 2-15%.
 4. The semiconductor device of claim 1, wherein said TiN layer has an oxygen content profile formed therein, said oxygen content profile showing an oxygen content at an upper surface of said TiN layer in the range from about 5-15% and an oxygen content at an interface of said TiN layer with said undoped HfO₂ layer in the range from about 0-7%.
 5. The semiconductor device of claim 4, wherein said oxygen content profile represents an oxygen gradient.
 6. The semiconductor device of claim 1, wherein said TiN layer has a bulk resistivity in a range from about 100-400 μΩcm or in a range from about 100-350 μΩcm or in a range from about 100-300 μΩcm.
 7. The semiconductor device of claim 1, wherein said TiN layer has a density in a range from about 4.5-5.2 g/cm³ or from about 4.55-5.15 g/cm³.
 8. The semiconductor device of claim 1, further comprising a gate structure with a gate dielectric formed over said substrate, said gate dielectric comprising said HfO₂ layer and said TiN layer.
 9. The semiconductor device of claim 8, wherein said HfO₂ layer is formed on an SiON layer.
 10. The semiconductor device of claim 1, further comprising a MIM or MIS capacitor structure with a dielectric structure formed over said substrate, said dielectric structure comprising said HfO₂ layer and said TiN layer.
 11. The semiconductor device of claim 10, wherein said HfO₂ layer is formed as a base electrode layer.
 12. A method for forming a semiconductor device, comprising: forming an undoped amorphous HfO₂ layer over a semiconductor substrate; forming a TiN layer on said undoped amorphous HfO₂ layer; and performing a thermal annealing process for at least partially inducing a ferroelectric phase in said undoped amorphous HfO₂ layer.
 13. The method of claim 12, wherein said TiN layer is deposited by performing a PVD process in an atmosphere comprising one of nitrogen and oxygen/nitrogen.
 14. The method of claim 13, wherein said PVD process is performed at temperatures smaller or equal than about 400° C. and preferably smaller or equal than about 300° C.
 15. The method of claim 14, further comprising adjusting a specific ratio of titanium/nitrogen when performing said PVD process.
 16. The method of claim 15, wherein said deposited TiN layer has an average oxygen content in a range from about 2%-30% or in a range from about 2-20% or in a range from about 2-15%.
 17. The method of claim 12, wherein said TiN layer is amorphous.
 18. The method of claim 12, wherein said undoped amorphous HfO₂ layer is formed by performing an ALD process to deposit a layer of undoped amorphous HfO₂ with a thickness in a range from 4-20 nm.
 19. The method of claim 18, wherein a deposition temperature during said ALD process is out of a range from about 200-400° C. or from about 200-300° C.
 20. The method of claim 12, wherein said thermal annealing process is performed at an annealing temperature of at least about 400° C. and at most about 1100° C. or at most about 800° C. 